Structure of human spermine oxidase in complex with a highly selective allosteric inhibitor.

Human spermine oxidase (hSMOX) plays a central role in polyamine catabolism. Due to its association with several pathological processes, including inflammation and cancer, hSMOX has garnered interest as a possible therapeutic target. Therefore, determination of the structure of hSMOX is an important step to enable drug discovery and validate hSMOX as a drug target. Using insights from hydrogen/deuterium exchange mass spectrometry (HDX-MS), we engineered a hSMOX construct to obtain the first crystal structure of hSMOX bound to the known polyamine oxidase inhibitor MDL72527 at 2.4 Å resolution. While the overall fold of hSMOX is similar to its homolog, murine N1-acetylpolyamine oxidase (mPAOX), the two structures contain significant differences, notably in their substrate-binding domains and active site pockets. Subsequently, we employed a sensitive biochemical assay to conduct a high-throughput screen that identified a potent and selective hSMOX inhibitor, JNJ-1289. The co-crystal structure of hSMOX with JNJ-1289 was determined at 2.1 Å resolution, revealing that JNJ-1289 binds to an allosteric site, providing JNJ-1289 with a high degree of selectivity towards hSMOX. These results provide crucial insights into understanding the substrate specificity and enzymatic mechanism of hSMOX, and for the design of highly selective inhibitors.

Development and characterization of rabbit monoclonal antibodies that recognize human spermine oxidase and application to immunohistochemistry of human cancer tissues.

The enzyme spermine oxidase (SMOX) is involved in polyamine catabolism and converts spermine to spermidine. The enzymatic reaction generates reactive hydrogen peroxide and aldehydes as by-products that can damage DNA and other biomolecules. Increased expression of SMOX is frequently found in lung, prostate, colon, stomach and liver cancer models, and the enzyme also appears to play a role in neuronal dysfunction and vascular retinopathy. Because of growing evidence that links SMOX activity with DNA damage, inflammation, and carcinogenesis, the enzyme has come into view as a potential drug target. A major challenge in cancer research is the lack of characterization of antibodies used for identification of target proteins. To overcome this limitation, we generated a panel of high-affinity rabbit monoclonal antibodies against various SMOX epitopes and selected antibodies for use in immunoblotting, SMOX quantification assays, immunofluorescence microscopy and immunohistochemistry. Immunohistochemistry analysis with the antibody SMAB10 in normal and transformed tissues confirms that SMOX is upregulated in several different cancers. Together, the panel of antibodies generated herein adds to the toolbox of high-quality reagents to study SMOX biology and to facilitate SMOX drug development.

Various expression-augmenting DNA elements benefit from STAR-Select, a novel high stringency selection system for protein expression.

The creation of highly productive mammalian cell lines often requires the screening of large numbers of clones, and even then expression levels are often low. Previously, we identified DNA elements, anti-repressor or STAR elements, that increase protein expression levels. These positive effects of STAR elements are most apparent when stable clones are established under high selection stringency. We therefore developed a very high selection system, STAR-Select, that allows the formation of few but highly productive clones. Here we compare the influence of STAR and other expression-augmenting DNA elements on protein expression levels in CHO-K1 cells. The comparison is done in the context of the often-used cotransfection selection procedure and in the context of the STAR-Select system. We show that STAR elements, as well as MAR elements induce the highest protein expression levels with both selection systems. Furthermore, in trans cotransfection of multiple copies of STAR and MAR elements also results in higher protein expression levels. However, highest expression levels are achieved with the STAR-Select selection system, when STAR elements or MARs are incorporated in a single construct. Our results also show that the novel STAR-Select selection system, which was developed in the context of STAR elements, is also very beneficial for the use of MAR elements.

Toxoplasmosis, an overview with emphasis on ocular involvement.

Toxoplasmosis is a common parasitic zoonosis and an important cause of abortions, mental retardation, encephalitis, blindness, and death worldwide. Although a large body of literature has emerged on the subject in the past decades, many questions about the pathogenesis and treatment of the disease remain unanswered. This review aims to provide an overview of the current insights regarding the causative parasite and the mechanisms leading to symptomatic infection with emphasis on ocular toxoplasmosis.

Conserved regions of protein disulfide isomerase are targeted by natural IgA antibodies in humans.

Secretory IgA (sIgA) antibodies in human tears and milk were found to recognize protein disulfide isomerase (PDI) on a Toxoplasma gondii lysate immunoblot (IB). These antibodies were already detectable in tears of infants. To determine the epitope containing-regions on PDI, we generated truncated versions of recombinant PDI that differ by 8-10 amino acids in length. By IB, it was found that the sIgA epitopes were confined to conserved regions of PDI, including the functionally essential thioredoxin-like domain. This suggested the capacity of sIgA to react with PDI of other species, which was confirmed by recognition of human PDI by IgA in tears. In contrast, anti-T. gondii PDI antibodies generated by immunization were not able to cross-react. Binding to the thioredoxin-like domain on IB could be gradually abrogated by incubation with peptide constituting the same domain. By consecutive investigation of the function of the protein targeted by sIgA, the presence of antibody in relation to age and analysis of the epitope constituting regions on PDI we demonstrate that sIgA directed against PDI are self-reactive natural antibodies. Furthermore, analysis of antibody epitopes on an antigen is a useful method to distinguish conventional, affinity-matured antibodies from natural antibodies. The presence at early age and continuity of anti-PDI sIgA in relation to age suggests the existence of B cells secreting germline-encoded antibodies in human mucosa outside of the gut. Overall, the PDI-specific antibodies are clearly part of the natural antibody repertoire, suggesting an active role for these antibodies in the innate defense against pathogens.

Protein disulfide isomerase of Toxoplasma gondii is targeted by mucosal IgA antibodies in humans.

Mass spectrometric analysis identified a 49 kDa antigen from Toxoplasma gondii as protein disulfide isomerase (PDI). This antigen is generally recognized by IgA in tears of healthy humans. We determined the complete open reading frame and expressed PDI recombinantly. Recombinant PDI was recognized by IgA in human tears known to contain antibodies specific for the 49 kDa antigen. High expression level and similarity to other protozoan PDIs suggest that T. gondii PDI might be a suitable target for recently described anti-protozoan drugs. PDI-specific antibodies clearly constitute part of the mucosal antibody repertoire possibly involved in defence against parasites.